Development of Multiscale Electrospun Scaffolds for Promoting Neural Differentiation of Induced Pluripotent Stem Cells

Khadem Mohtaram, Nima

12 December 2014

Electrospun biomaterial scaffolds can be engineered to support the neural differentiation of induced pluripotent stem cells. As electrospinning produces scaffolds consisting of nano or microfibers, these topographical features can be used as cues to direct stem cell differentiation. These nano and microscale scaffolds can also be used to deliver chemical cues, such as small molecules and growth factors, to direct the differentiation of induced pluripotent stem cells into neural phenotypes. Induced pluripotent stem cells can become any cell type found in the body, making them a powerful tool for engineering tissues. Therefore, a combination of an engineered biomaterial scaffold with induced pluripotent stem cells is a promising approach for neural tissue engineering applications. As detailed in this thesis, electrospun scaffolds support the neuronal differentiation of induced pluripotent stem cells through delivering the appropriate chemical cues and also presenting physical cues, specifically topography to enhance neuronal regeneration. This thesis seeks to evaluate the following topics: multifunctional electrospun scaffolds for promoting neuronal differentiation of induced pluripotent stem cells, neuronal differentiation of human induced pluripotent stem cells seeded on electrospun scaffolds with varied topographies, and controlled release of glial cell-derived neurotrophic factor from random and aligned electrospun nanofibers. / Graduate / nkhadem@uvic.ca

Neural Tissue Engineering

Induced Pluripotent Stem Cells

Spinal Cord Injuries

Photopolymerizable scaffolds of native extracellular matrix components for tissue engineering applications

Suri, Shalu

24 January 2011

In recent years, significant success has been made in the field of regenerative medicine. Tissue engineering scaffolds have been developed to repair and replace different types of tissues. The overall goal of the current work was to develop scaffolds of native extracellular matrix components for soft tissue regeneration, more specifically, neural tissue engineering. To date, much research has been focused on developing a nerve guidance scaffold for its ability to fill and heal the gap between the damaged nerve ends. Such scaffolds are marked by several intrinsic properties including: (1) a biodegradable scaffold or conduit, consisting of native ECM components, with controlled internal microarchitecture; (2) support cells (such as Schwann cells) embedded in a soft support matrix; and (3) sustained release of bioactive factors. In the current dissertation, we have developed such scaffolds of native biomaterials including hyaluronic acid (HA) and collagen. HA is a nonsulphated, unbranched, high-molecular weight glycosaminoglycan which is ubiquitously secreted by cells in vivo and is a major component of extracellular matrix (ECM). High concentrations of HA are found in cartilage tissue, skin, vitreous humor, synovial fluid of joints and umbilical cord. HA is nonimmunogenic, enzymatically degradable, non-cell adhesive which makes HA an attractive material for biomedical research. Here we developed new photopolymerizable HA based materials for soft tissue repair application. First, we developed interpenetrating polymer networks (IPN) of HA and collagen with controlled structural and mechanical properties. The IPN hydrogels were enzymatically degradable, porous, viscoelastic and cytocompatible. These properties were dependent on the presence of crosslinked networks of collagen and GMHA and can be controlled by fine tuning the polymer ratio. We further developed these hydrogel constructs as three dimensional cellular constructs by encapsulating Schwann cells in IPN hydrogels. The hydrogel constructs supported cell viability, spreading, proliferation, and growth factor release from the encapsulated cells. Finally, we fabricated scaffolds of photopolymerizable HA with controlled microarchitecture and developed designer scaffolds for neural repair using layer-by-layer fabrication technique. Lastly, we developed HA hydrogels with unique anisotropic swelling behavior. We developed a dual-crosslinking technique in which a super-swelling chemically crosslinked hydrogel is patterned with low-swelling photocrosslinked regions. When this dual-crosslinked hydrogel is swelled it contorts into a new shape because of differential swelling among photopatterned regions. / text

Neural tissue engineering

Tissue engineering

Hydrogels

Hyaluronic acid

Collagen

Electroconductive neural interfaces for neural tissue applications

Lee, Jae Young, 1974-

26 October 2010

Creating effective cellular interfaces that can provide specific cellular signals is important for a number of fields ranging from tissue engineering to biosensors. Electroconducting polymers, especially polypyrrole (PPy), have attracted much attention for use in numerous biomedical applications since they provide a potential platform for local delivery of electrical stimuli to target tissues. To effectively modulate cellular functions at neural interfaces, it is essential to incorporate a range of extracellular cues into conducting polymers according to specific applications, such as nerve guidance conduits and implantable neural probes. For nerve regeneration scaffolds, three dimensional forms are desired for control of critical properties, such as porosity, mechanical strength, and topography. However, most researchers have worked on conventional two-dimensional PPy films, which cannot mimic a native three-dimensional architecture. Thus, a portion of my work has focused on introducing three-dimensional nanofibrous features into PPy. I have investigated various coating conditions to obtain uniform and conductive nanofibers. Effectiveness of electrical stimulation through the conducting nanofibers was confirmed by in vitro PC12 cell culture. The effects of different conducting nanofiber topographies (random and aligned) on cell adhesion and neurite outgrowth were examined in conjunction with electrical stimulation. The benefits of immobilized-NGF could be combined with electrical stimuli, which could be an ideal platform for neural tissue engineering scaffolds. Thus, I have modified conducting polymers to display neurotrophic activity. Nerve growth factor (NGF) was chemically immobilized on two dimensional and three dimensional PPy substrates. Specific chemical conjugation was achieved and characterized using diverse techniques. Immobilized NGF was as effective as exogenous NGF in medium in inducing neurite development and extension. NGF immobilized on functionalized PPy substrates was stable in a physiological solution and under electrical stimulation, indicating effective prolonged activity. I also investigated another important application of conducting polymer-based materials for neural interfacing - passivating electrodes with a biocompatible polysaccharide, hyaluronic acid (HA). I synthesized electrically polymerizable HA by chemically conjugating amine-functionalized pyrrole derivatives with HA. This coating was stable under physiological conditions for three months and resistant to enzymatic degradation. In vitro studies have shown the minimal adhesion and migration of astrocytes on the HA-coated electrodes. Implantation of HA-coated commercial probes into rat cortices for three weeks revealed attenuated reactive astrocyte responses from the coated wires, and the importance of glial interaction with non-conducting sites was demonstrated. / text

Neural interface

Polypyrrole

Neural tissue engineering

Neural probe

Nerve growth factor

Biomaterials

Polymers

Electroconducting polymers

Understanding the role topographical features play in stimulating the endogenous peripheral nerve regeneration across critically sized nerve gaps

Mukhatyar, Vivek

11 November 2011

Severe traumatic injuries and surgical procedures like tumor resection often create peripheral nerve gaps, accounting for over 250,000 injuries in the US annually. The clinical "gold standard" for bridging peripheral nerve gaps is autografts, with which 40-50% of patients regain useful function. However, issues including their limited availability and collateral damage at the donor site limit the effectiveness and use of autografts. Therefore, it is critical to develop alternative bioengineered approaches that match or exceed autograft performance. With the use of guidance channels, the endogenous regeneration process spontaneously occurs when successful bridging of short gaps (< 10mm) occurs, but fails to occur in the bridging of longer gaps (≥15mm). Several bioengineered strategies are currently being explored to bridge these critical size nerve gaps. Other labs and ours have shown how filler materials that provide topographical cues within the nerve guides are able to enhance nerve growth and bridge critical length gaps in rats. However, the mechanism by which intra-luminal fillers enhance nerve regeneration has not been explored. The main goal of this dissertation was to explore the interplay between intra-luminal scaffolds and orchestrated events of provisional fibrin matrix formation, glial cell infiltration, ECM deposition and remodeling, and axonal infiltration - a sequence we term the 'regenerative' sequence. We hypothesized that the mechanism by which thin films with topographical cues enhance regeneration is by serving as physical 'organizing templates' for Schwann cell infiltration, Schwann cell orientation, extra-cellular matrix deposition/organization and axon infiltration. We demonstrate that aligned topographical cues mediate their effects to the neuronal cells through optimizing fibronectin adsorption in vitro. We also demonstrate that aligned electrospun thin films are able to enhance bridging of a critical length nerve gap in vivo by stabilizing the provisional matrix, creating a pro-inflammatory environment and influencing the maturation of the regenerating cable leading to faster functional recovery compared to smooth films and random fibers. This research will advance our understanding of the mechanisms of peripheral nerve regeneration, and help develops technologies that are likely to improve clinical outcomes after peripheral nerve injury.

Biomaterials

Neural tissue engineering

Topography

Regenerative medicine

Autotransplantation

Autografts

Tissue engineering

Nervous system Regeneration

Culture of human pluripotent stem cells and neural networks in 3D using an optogenetic approach and a hydrogel model

Lee, Si Yuen

January 2016

Development of optogenetically controllable human neural network models can provide an investigative system that is relevant to the human brain. Conventional cultures of neural networks in two-dimensions (2D) have major limitations of scale. For instance, the soma of neurons in 2D is unrealistically flattened and both axon and dendrite outgrowth is restricted. Using a combination of tissue engineering techniques and the inclusion of optogenetically modified human induced pluripotent stem cell (hiPSC)-derived neural progenitor cells (NPCs), the development of a three-dimensional (3D) human neural culture model within a defined 3D microenvironment is investigated in this study. Light-sensitive neurons were successfully generated by transducing Channelrhodopsin-2 (ChR2) into human iPSC-derived NPCs and neuroblastoma cells (SH-SY5Y) using lentiviral transduction. The use of neuron specific promoters for synapsin-1 (SYN1) and calcium-calmodulin kinase II (CaMKII) in driving the expression of ChR2-Yellow Florescent Protein (YFP) within the mixed neuronal populations from hiPSC-derived neurons (Axol cells) were compared. Viability of the cells at 7 day-post-infection was 80&percnt; - 97&percnt; in all conditions tested. In line with published literature, transduction efficiency of neurons at day 14 was found to be 3&percnt; - 7&percnt; for plasmids containing the SYN1 promoter and 2&percnt; - 5&percnt; for plasmids containing the CaMKII promoter. An increase in promoter driven ChR2-YFP expression was evaluated over 28 days as the neural subpopulations matured. Stably ChR2 expression continued through-out higher passages (&ge; P₁₀) and possibly for periods up to several months. Both SYN1 and CaMKII promoters were found to drive the expression of ChR2 in Axol cells targeting inhibitory and excitatory neurons, respectively. 3D culture systems to support cell growth and optogenetic application were developed and characterised. Alginate hydrogel functionalised with short peptide sequence arginine-glycine-aspartate (RGD), and small molecules such as Rho Kinase inhibitor (ROCKi) and ZVAD were incorporated to increase the viability of human pluripotent stem cells (hPSCs). Investigation of cell response reveals that a flow rate of 3 ml/min and an alginate concentration of 1.8&percnt; (w/v) are optimal and that stem cell survival is significantly improved through incorporation of RGD and ROCKi. Interestingly, ChR2-YFP expression of Axol and SY5Y cells was detectable when transferred to the 3D culture system. The optogenetically modified neurons were found responsive to light stimulation, showing firing patterns and calcium events typical of early developing neurons (e.g. mixed and burst waves; single and multipeak spikes). Neuronal activities were assessed using calcium imaging. Higher numbers of calcium events were associated with CaMKII driven ChR2-YFP expression than with SYN1 in Axol cells. However, calcium activity in SH-SY5Y cells was most noticeable in neurons expressing ChR2-YFP driven by the SYN1 promoter. In primary rodent neuronal cultures, synchronous calcium firing with repetitive action potentials (APs) resulted from ChR2-YFP expression was driven by both SYN1 and CaMKII promoter upon light stimulation. By combining multi-approaches, we report for the first time on the generation of an in vitro hiPSC-derived neural network model in 3D using functionalised alginate hydrogel and involving optogenetic targeting. Expression of ChR2-YFP was found driven by both SYN1 and CaMKII promoter in the RGD-alginate bead system that cultured with Axol cells.

Fiber Scaffolds of Poly (glycerol-dodecanedioate) and its Derivative via Electrospinning for Neural Tissue Engineering

Dai, Xizi

27 March 2015

Peripheral nerves have demonstrated the ability to bridge gaps of up to 6 mm. Peripheral Nerve System injury sites beyond this range need autograft or allograft surgery. Central Nerve System cells do not allow spontaneous regeneration due to the intrinsic environmental inhibition. Although stem cell therapy seems to be a promising approach towards nerve repair, it is essential to use the distinct three-dimensional architecture of a cell scaffold with proper biomolecule embedding in order to ensure that the local environment can be controlled well enough for growth and survival. Many approaches have been developed for the fabrication of 3D scaffolds, and more recently, fiber-based scaffolds produced via the electrospinning have been garnering increasing interest, as it offers the opportunity for control over fiber composition, as well as fiber mesh porosity using a relatively simple experimental setup. All these attributes make electrospun fibers a new class of promising scaffolds for neural tissue engineering. Therefore, the purpose of this doctoral study is to investigate the use of the novel material PGD and its derivative PGDF for obtaining fiber scaffolds using the electrospinning. The performance of these scaffolds, combined with neural lineage cells derived from ESCs, was evaluated by the dissolvability test, Raman spectroscopy, cell viability assay, real time PCR, Immunocytochemistry, extracellular electrophysiology, etc. The newly designed collector makes it possible to easily obtain fibers with adequate length and integrity. The utilization of a solvent like ethanol and water for electrospinning of fibrous scaffolds provides a potentially less toxic and more biocompatible fabrication method. Cell viability testing demonstrated that the addition of gelatin leads to significant improvement of cell proliferation on the scaffolds. Both real time PCR and Immunocytochemistry analysis indicated that motor neuron differentiation was achieved through the high motor neuron gene expression using the metabolites approach. The addition of Fumaric acid into fiber scaffolds further promoted the differentiation. Based on the results, this newly fabricated electrospun fiber scaffold, combined with neural lineage cells, provides a potential alternate strategy for nerve injury repair.

Embryonic Stem Cells

Motor Neuron differentiation

Metabolites

Poly (glycerol-dodecanedioate)

Electrospinning

Fiber scaffolds

Neural Tissue Engineering

Biomaterials